Carboxyl-terminal peptides from histone H1 variants: DNA binding characteristics and solution conformation

The carboxyl-terminal domains of the histone H1 proteins bind to DNA and are important in condensation of DNA. Little is known about the details of the interactions between H1 histones and DNA, and in particular, there is little known about differences among variant H1 histones in their interactions with DNA. Questions concerning H1 histone-DNA affinity and H1 conformation were investigated using peptide fragments from the carboxyl terminal domains of four nonallelic histone H1 variant proteins (mouse H1-1, H1-4 and H1^°, and rat H1T). Three of the four peptides showed a slight preference for binding to a GC-rich region of a 214-base-pair DNA fragment, rather than to an AT-rich region. The fourth peptide, H1t, appeared to bind preferentially to the AT-rich region of the 214-base-pair fragment. The results show that these small peptides bind preferentially to a subset of DNA sequences; such sequence preference might be exhibited by the intact H1 histones themselves. CD spectra of the peptides, which are from regions of the proteins that are not compactly folded, showed that the α-helical content of the peptides was minimal if the peptides were in 10 mM phosphate buffer, but increased if the peptides were in 1 M NaClO₄ and 50% trifluoroethanol, conditions that are postulated to approximate certain aspects of binding to DNA. H1-4 peptide, which was predicted to be 70% α-helix, but was not α-helical in 10 mM phosphate buffer, appeared from difference CD spectra to be more α-helical when it was bound to DNA. The regions of the proteins from which these peptides are derived, which are extended in solution, may fold, forming α-helices, upon binding to DNA. © 1996 John Wiley & Sons, Inc.     

Conformation of reconstituted mononucleosomes and effect of linker histone H1 binding studied by scanning force microscopy

The conformation of mononucleosome complexes reconstituted with recombinant core histones on a 614-basepair-long DNA fragment containing the Xenopus borealis 5S rRNA nucleosome positioning sequence was studied by scanning/atomic force microscopy in the absence or presence of linker histone H1. Imaging without prior fixation was conducted with air-dried samples and with mononucleosomes that were injected directly into the scanning force microscopy fluid cell and visualized in buffer. From a quantitative analysis of approximately 1,700 complexes, the following results were obtained: i), In the absence of H1, a preferred location of the nucleosome at the X. borealis 5S rRNA sequence in the center of the DNA was detected. From the distribution of nucleosome positions, an energy difference of binding to the 5S rRNA sequence of DeltaDeltaG approximately 3 kcal mol(-1) as compared to a random sequence was estimated. Upon addition of H1, a significantly reduced preference of nucleosome binding to this sequence was observed. ii), The measured entry-exit angles of the DNA at the nucleosome in the absence of H1 showed two maxima at 81 +/- 29 degrees and 136 +/- 18 degrees (air-dried samples), and 78 +/- 25 degrees and 137 +/- 25 degrees (samples imaged in buffer solution). In the presence of H1, the species with the smaller entry-exit angle was stabilized, yielding average values of 88 +/- 34 degrees for complexes in air and 85 +/- 10 degrees in buffer solution. iii), The apparent contour length of the nucleosome complexes was shortened by 34 +/- 13 nm as compared to the free DNA due to wrapping of the DNA around the histone octamer complex. Considering an 11 nm diameter of the nucleosome core complex, this corresponds to a total of 145 +/- 34 basepairs that are wound around the nucleosome.     

A rat histone H4 gene closely associated with the testis-specific H1t gene

A rat histone H4 gene closely associated with the testis-specific H1t gene was isolated by screening the Sargent-Bonner rat genomic library using cloned human histone genes as probes. Both the H4 gene and the H1t gene are located on a 7-kb EcoRI genomic DNA fragment. Although the deduced amino acid sequence of the rat H4 histone is identical to that of the sequence of human histone H4, the nucleotide sequence of the coding region differs significantly from the coding region of the human H4 gene. Moreover, the relative spacing between the 5'-consensus sequence elements is unique for an H4 gene. S1-nuclease protection analyses reveal that both the H4 and H1t mRNA species are present in a fraction of rat testis cells highly enriched in pachytene spermatocytes, while only the H4 mRNA species is present in a rat myeloma cell line (Y3-Ag1.2.3). During a 1-h hydroxyurea treatment of the Y3 cells, which produces a 99% inhibition of DNA synthesis, the level of this H4 mRNA drops by only 50%, indicating that the stability of this mRNA is only partially coupled with DNA synthesis.     

Preferential binding of simian virus 40 T-antigen dimers to origin region I.

The sequence components that direct high-affinity binding of simian virus 40 (SV40) T antigen to SV40 origin region I are composed of two recognition pentanucleotides separated by a spacer. This region has binding sites for two T-antigen monomeric units. We extended the tripartite region I sequence by one and two sets of spacers and pentanucleotides and also shortened the region by one pentanucleotide. Our T-antigen-binding studies with these constructs show that the protein has a strong preference for binding to an even rather than an odd number of pentanucleotides separated by spacer sequences. Gel retardation assays reveal that the size of the complex formed between the 17-base-pair region I sequence and T antigen did not increase when the sequence was extended with one spacer-pentanucleotide sequence but did increase with two such units. DNase I footprinting and fragment assay experiments indicate that the protein did not protect a pentanucleotide that was not paired with another pentanucleotide. The unpaired pentanucleotide resumed its binding activity when it was paired with a spacer and another pentanucleotide sequence. We propose that T antigen binds to region I as a preformed dimer.     

Histone H1 interacts preferentially with DNA fragments containing a cisplatin-induced 1,2-intrastrand cross-link

Cisplatin [cis-diamminedichloroplatinum(II) or cis-DDP], but not its stereoisomer transplatin, is suggested to be among the most powerful anticancer agents. It is believed that its therapeutic activity results from its interaction with DNA forming intra- and interstrand crosslinks. During our earlier investigations, we have observed a prominent preference of the linker histone H1 for binding to cis-platinated DNA (containing several different cross-links along the DNA fragment) compared with unmodified or transplatin-modified DNA. This report presents our recent experimental data obtained by band-shift analysis on the binding of H1 to a cisplatin-modified synthetic 34 bp DNA fragment containing a single target d(GG/CC) for 1,2 cis-intra-platination. Results obtained with another nuclear protein with similar DNA-binding properties, HMGB1, are also presented. The experimental data throw light on the precise preference of histone H1 for binding to different types of cisplatin-created cross-links in DNA.     

Separation of nucleosomes containing histones H1 and H5

Hen erythrocyte chromatin was digested with staphylococcal nuclease and fractionated by electrophoresis in polyacrylamide gels. Instead of the three bands described for mouse carcinoma chromatin, four main discrete components (MN1, MN2, MN2E and MN3) were resolved in the mononucleosome fraction of erythrocyte chromatin. MN2 contained all five histones and a DNA fragment of 165–180 base pairs. MN2E comprised four nucleosomal histones plus histone H5 (but not H1) and a DNA fragment of 170–190 base pairs. The relatively nuclease resistant MN3 fraction of erythrocyte nucleosomes contained H1 but no H5 histone. A more accurate analysis of the MN2 fraction in mouse carcinoma nucleosomes revealed some additional microheterogeneity depending on the presence of two different subfractions of H1.     

Studies on the interaction of H1 histone with superhelical DNA: characterization of the recognition and binding regions of H1 histones.

The very lysine rich histone, H1, isolated from a variety of sources interacts preferentially with superhelical DNA compared to relaxed DNA duplexes. The nature of this specific interaction has been investigated by studying the ability of various purified fragments of H1 histone from calf thymus to recognize and bind superhelical DNA. The data suggest that the globular region of the H1 histone molecule (amino acid residues 72-106) is involved in the recognition of superhelical DNA. Thus, the H1 histone carboxy-terminal fragment, 72-212, resembles native H1 histone both quantitatively and qualitatively in its ability to discriminate between and bind to superhelical and relaxed DNA while the H1 histone carboxy-terminal fragment, residues 106-212, has lost this specificity, binding superhelical and relaxed DNA equally well. Furthermore, under conditions in which the globular region of the intact H1 histone has been unfolded, the molecule loses its ability to discriminate between superhelical and relaxed DNA, and binds both forms of DNA equally.     

Direct evidence for specific binding of the replicative origin of the Escherichia coli chromosome to the membrane.

The origin of replication of the Escherichia coli chromosomal DNA binds with high affinity to outer membrane preparations. This specific binding requires a 463-base-pair region of origin DNA between positions -45 and +417 of the oriC map. We show that binding does not require the presence of adjacent regions. From further analysis, we conclude that more than one binding site resides within the 325-base-pair fragment between positions +38 (BamHI) and +417 (XhoI). When this fragment is cut, two pieces bind with high affinity and one binds with lesser affinity. The binding ability of one of the high affinity sites is abolished by cutting it at position +92 with BamHI.     

Structuring of H1 histone. Evidence of high-affinity binding sites for phosphate ions

Circular dichroism studies show that low concentrations of phosphate ions induce folding of the H1 histones. Sulfate and perchlorate anions have effects similar to phosphate indicating the presence on H1 histones of binding sites with high affinity for ions with tetrahedral geometry. In fact, the structuring efficiency of different ions, as determined by the midpoint value of the effect/concentration curve, is 0.05 M for NaCl, 0.005 M for NaClO4, 0.001 M for sodium phosphate and 0.0003 M for sodium sulfate on H1 histone from Chaetopterus variopedatus sperm chromatin. Phosphate shows similar folding efficiency also on calf thymus and on sea-urchin sperm H1 histones. The effect of phosphate ions on the H1 molecule is observed also by differential absorption spectroscopy in the region of absorption of amino acid side-chains. Binding studies by gel filtration chromatography on Sephadex columns show that phosphate binding occurs in the presence of structuring concentrations of sodium chloride. About 9 ATP molecules bind to H1 histones derived from non-active cell chromatins while only 3.5 ATP molecules bind to H1 derived from active somatic chromatins. The fluorescence of the tyrosine residues of Chaetopterus sperm H1 is enhanced by chloride ions and heavily quenched by phosphate ions in correlation with structuring of the molecule, demonstrating direct interactions between tyrosine residues and phosphate ions. The defined and limited number of phosphate groups bound per histone molecule, the high affinity of the interaction and the effect on the structure of the histone suggest the participation of phosphate groups in the binding of H1 histones to DNA.     

N- and C-terminal domains determine differential nucleosomal binding geometry and affinity of linker histone isotypes H1(0) and H1c

Eukaryotic linker or H1 histones modulate DNA compaction and gene expression in vivo. In mammals, these proteins exist as multiple isotypes with distinct properties, suggesting a functional significance to the heterogeneity. Linker histones typically have a tripartite structure composed of a conserved central globular domain flanked by a highly variable short N-terminal domain and a longer highly basic C-terminal domain. We hypothesized that the variable terminal domains of individual subtypes contribute to their functional heterogeneity by influencing chromatin binding interactions. We developed a novel dual color fluorescence recovery after photobleaching assay system in which two H1 proteins fused to spectrally separable fluorescent proteins can be co-expressed and their independent binding kinetics simultaneously monitored in a single cell. This approach was combined with domain swap and point mutagenesis to determine the roles of the terminal domains in the differential binding characteristics of the linker histone isotypes, mouse H1(0) and H1c. Exchanging the N-terminal domains between H1(0) and H1c changed their overall binding affinity to that of the other variant. In contrast, switching the C-terminal domains altered the chromatin interaction surface of the globular domain. These results indicate that linker histone subtypes bind to chromatin in an intrinsically specific manner and that the highly variable terminal domains contribute to differences between subtypes. The methods developed in this study will have broad applications in studying dynamic properties of additional histone subtypes and other mobile proteins.     

Histone H2A ubiquitination does not preclude histone H1 binding, but it facilitates its association with the nucleosome

Histone H2A ubiquitination is a bulky posttranslational modification that occurs at the vicinity of the binding site for linker histones in the nucleosome. Therefore, we took several experimental approaches to investigate the role of ubiquitinated H2A (uH2A) in the binding of linker histones. Our results showed that uH2A was present in situ in histone H1-containing nucleosomes. Notably in vitro experiments using nucleosomes reconstituted onto 167-bp random sequence and 208-bp (5 S rRNA gene) DNA fragments showed that ubiquitination of H2A did not prevent binding of histone H1 but it rather enhanced the binding of this histone to the nucleosome. We also showed that ubiquitination of H2A did not affect the positioning of the histone octamer in the nucleosome in either the absence or the presence of linker histones.     

Differences among subfractions of H1 histone in retention of linear and superhelical DNA on filters

Four kinds of rabbit thymus H1 histone differ among themselves in their ability to retain DNA on nitrocellulose filters. This is true for linear, or superhelical DNA, but the order of effectiveness of the different H1 histones depends on the physical conformation of the DNA. For linear DNA the binding efficiencies of the H1 histones are: RTL2 = RTL3 greater than RTL4 greater than RTL1. This order of effectiveness parallels the effectiveness of the H1 histones previously found for the condensation of linear DNA as observed by circular dichroism and viscosity. The binding efficiencies of the various histones toward superhelical DNA were: RTL4 greater than RTL3 greater than RTL1 greater than RTL2. The variation in amino acid sequence between different rabbit thymus H1 histones might thus introduce structural variations in nucleohistone fibers and perhaps in chromatin.